/* -*-c++-*- OpenSceneGraph - Copyright (C) 1998-2006 Robert Osfield
 *
 * This library is open source and may be redistributed and/or modified under
 * the terms of the OpenSceneGraph Public License (OSGPL) version 0.0 or
 * (at your option) any later version.  The full license is in LICENSE file
 * included with this distribution, and on the openscenegraph.org website.
 *
 * This library is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * OpenSceneGraph Public License for more details.
*/
//osgParticle - Copyright (C) 2002 Marco Jez

#ifndef OSGPARTICLE_RADIAL_SHOOTER
#define OSGPARTICLE_RADIAL_SHOOTER 1

#include <osgParticle/Shooter>
#include <osgParticle/Particle>
#include <osgParticle/range>

#include <osg/CopyOp>
#include <osg/Object>
#include <osg/Math>

namespace osgParticle
{

    /**    A shooter class that shoots particles radially.
        This shooter computes the velocity vector of incoming particles by choosing a
        random direction and a random speed. Both direction and speed are chosen within
        specified ranges. The direction is defined by two angles: <B>theta</B>, which
        is the angle between the velocity vector and the Z axis, and <B>phi</B>, which is
        the angle between the X axis and the velocity vector projected onto the X-Y plane.
    */
    class RadialShooter: public Shooter {
    public:
        inline RadialShooter();
        inline RadialShooter(const RadialShooter& copy, const osg::CopyOp& copyop = osg::CopyOp::SHALLOW_COPY);

        META_Object(osgParticle, RadialShooter);

        /// Get the range of possible values for <B>theta</B> angle.
        inline const rangef& getThetaRange() const;

        /// Set the range of possible values for <B>theta</B> angle.
        inline void setThetaRange(const rangef& r);

        /// Set the range of possible values for <B>theta</B> angle.
        inline void setThetaRange(float r1, float r2);

        /// Get the range of possible values for <B>phi</B> angle.
        inline const rangef& getPhiRange() const;

        /// Set the range of possible values for <B>phi</B> angle.
        inline void setPhiRange(const rangef& r);

        /// Set the range of possible values for <B>phi</B> angle.
        inline void setPhiRange(float r1, float r2);

        /// Get the range of possible values for initial speed of particles.
        inline const rangef& getInitialSpeedRange() const;

        /// Set the range of possible values for initial speed of particles.
        inline void setInitialSpeedRange(const rangef& r);

        /// Set the range of possible values for initial speed of particles.
        inline void setInitialSpeedRange(float r1, float r2);

        /// Get the range of possible values for initial rotational speed of particles.
        inline const rangev3& getInitialRotationalSpeedRange() const;

        /// Set the range of possible values for initial rotational speed of particles.
        inline void setInitialRotationalSpeedRange(const rangev3& r);

        /// Set the range of possible values for initial rotational speed of particles.
        inline void setInitialRotationalSpeedRange(const osg::Vec3& r1, const osg::Vec3& r2);

        /// Shoot a particle. Do not call this method manually.
        inline void shoot(Particle* P) const;

    protected:
        virtual ~RadialShooter() {}
        RadialShooter& operator=(const RadialShooter&) { return *this; }

    private:
        rangef _theta_range;
        rangef _phi_range;
        rangef _speed_range;
        rangev3 _rot_speed_range;
    };

    // INLINE FUNCTIONS

    inline RadialShooter::RadialShooter()
    :    Shooter(),
        _theta_range(0, 0.5f*osg::PI_4),
        _phi_range(0, 2*osg::PI),
        _speed_range(10, 10),
        _rot_speed_range(osg::Vec3(0,0,0), osg::Vec3(0,0,0))
    {
    }

    inline RadialShooter::RadialShooter(const RadialShooter& copy, const osg::CopyOp& copyop)
    :    Shooter(copy, copyop),
        _theta_range(copy._theta_range),
        _phi_range(copy._phi_range),
        _speed_range(copy._speed_range),
        _rot_speed_range(copy._rot_speed_range)
    {
    }

    inline const rangef& RadialShooter::getThetaRange() const
    {
        return _theta_range;
    }

    inline const rangef& RadialShooter::getPhiRange() const
    {
        return _phi_range;
    }

    inline const rangef& RadialShooter::getInitialSpeedRange() const
    {
        return _speed_range;
    }

    inline const rangev3& RadialShooter::getInitialRotationalSpeedRange() const
    {
        return _rot_speed_range;
    }

    inline void RadialShooter::setThetaRange(const rangef& r)
    {
        _theta_range = r;
    }

    inline void RadialShooter::setThetaRange(float r1, float r2)
    {
        _theta_range.minimum = r1;
        _theta_range.maximum = r2;
    }

    inline void RadialShooter::setPhiRange(const rangef& r)
    {
        _phi_range = r;
    }

    inline void RadialShooter::setPhiRange(float r1, float r2)
    {
        _phi_range.minimum = r1;
        _phi_range.maximum = r2;
    }

    inline void RadialShooter::setInitialSpeedRange(const rangef& r)
    {
        _speed_range = r;
    }

    inline void RadialShooter::setInitialSpeedRange(float r1, float r2)
    {
        _speed_range.minimum = r1;
        _speed_range.maximum = r2;
    }

    inline void RadialShooter::setInitialRotationalSpeedRange(const rangev3& r)
    {
        _rot_speed_range = r;
    }

    inline void RadialShooter::setInitialRotationalSpeedRange(const osg::Vec3& r1, const osg::Vec3& r2)
    {
        _rot_speed_range.minimum = r1;
        _rot_speed_range.maximum = r2;
    }

    inline void RadialShooter::shoot(Particle* P) const
    {
        float theta = _theta_range.get_random();
        float phi = _phi_range.get_random();
        float speed = _speed_range.get_random();
        osg::Vec3 rot_speed = _rot_speed_range.get_random();

        P->setVelocity(osg::Vec3(
            speed * sinf(theta) * cosf(phi),
            speed * sinf(theta) * sinf(phi),
            speed * cosf(theta)
            ));

        P->setAngularVelocity(rot_speed);
    }

}


#endif
